DE102020133013A1 - Compensation of thermal deformation on sonotrodes - Google Patents

Abstract

The present invention relates to a sonotrode for an ultrasonic welding device with a lower section of length u and an upper section of length o, the upper section and the lower section being arranged next to one another on a longitudinal axis of the sonotrode and the total length of the sonotrode in the direction of the longitudinal axis u + o, the lower section having a sealing surface oriented perpendicularly to the longitudinal axis, the sealing surface being intended to come into contact with a material to be processed. In order to provide a sonotrode for an ultrasonic welding device, with which even very thin layers of material can be welded together with high quality, it is proposed according to the invention that the lower section has a slit, the slit extending from the sealing surface to a side of the lower part opposite the sealing surface Section extends, so that the lower portion of the sonotrode is divided into several, in a direction perpendicular to the longitudinal axis adjacent segments.

Description

The present invention relates to a sonotrode for an ultrasonic welding device with a lower section of length u and an upper section of length o, the upper section and the lower section being arranged next to one another on a longitudinal axis of the sonotrode and the overall length of the sonotrode in the direction of the longitudinal axis u + o, the lower section having a sealing surface oriented perpendicularly to the longitudinal axis, the sealing surface being intended to come into contact with a material to be processed.

Ultrasonic welding has been an established process for some time when it comes to connecting thermoplastics with one another in a form-fitting or material-locking manner. The areas of application range from the automotive and electrical industries to the packaging, medical and hygiene industries.

Typical ultrasonic welding devices have an ultrasonic generator, a converter, possibly an amplitude transformer and a welding tool, the so-called sonotrode. The ultrasonic generator generates a high voltage in the desired ultrasonic frequency from the applied mains voltage. The electrical oscillation of the ultrasonic generator is then converted into a mechanical longitudinal oscillation using the inverse piezoelectric effect in the converter and transmitted to the amplitude transformer or the welding tool. The amplitude of the mechanical vibration can be increased or decreased with the aid of the amplitude transformer, which is optionally arranged between the converter and the welding tool. In addition, the amplitude transformer can also be used to hold the oscillating structure consisting of converter, amplitude transformer and welding tool. Finally, as the actual, active welding tool, the sonotrode transfers the mechanical vibrations to the components to be joined. The sonotrode has a sealing surface via which the sonotrode comes into contact with the material to be processed.

Due to the mechanical vibrations with frequencies in the ultrasonic range, frictional heat is generated in the plastic to be joined and the molecules in the plastic are stimulated to move. As a result, the plastic softens and begins to melt, so that the components to be joined connect when a certain pressure is applied to the components over a certain period of time. The components are then firmly connected to one another at the molecular level.

The properties of the welded joint produced in terms of strength, tightness and visual impression depend on various factors during ultrasonic welding. On the one hand, the frequency and amplitude of the vibration used during welding play a role, and on the other hand, the duration and the applied welding force also influence the end result of the weld. In addition, the welding result also depends on the geometric or spatial shape of the welding tool. The shape of the welding tool is therefore selected in advance so that a specific welding result is achieved, for example with regard to the visual impression.

However, the shape of the welding tool, i.e. the sonotrode, can also change during the welding process. Temperature differences within the sonotrode occur during the welding process, which lead to uneven thermal expansion of the sonotrode material. This leads to partially convex sealing surfaces, which strongly influence the welding result depending on the material to be welded. In particular, this severely limits the homogeneous welding of very thin material layers, such as nonwovens, which are used in the medical industry or for hygiene products. During production, there are fluctuations in the result of both the strength of the connection and the visual impression of the welded connection. This is due to the fact that, for the welding of very thin layers of material, a distance between the welding tool and a counter-tool, between which the layers of material are arranged, must be selected to be correspondingly small in order to achieve a weld. If this distance is only in the range of a few micrometers, for example, the deformation of the sealing surface of the sonotrode, which is also only in the range of a few micrometers, results in a relatively significant local change in the distance between the welding tool and the counter tool. As a result, too little pressure is applied to the materials to be joined in some areas, while too much pressure is applied in other areas.

In order to solve or minimize this problem, it is known in the prior art to concavely grind the sealing surfaces that come into contact with the material to be processed. The concave indentation in the sealing surface is then canceled out by the convex thermal expansion of the sonotrode material, so that an even surface is formed during operation of an ultrasonic welding device gel surface and thus a homogeneous weld is achieved.

The disadvantage of this solution is that the deformation is ideally compensated for only at a very specific operating point of the ultrasonic welding device. When starting the ultrasonic welding device from the cold state or when the tool heats up more than originally planned, this optimal operating point is not reached and a homogeneous weld is therefore not achieved either.

In order to nevertheless achieve a processing result that is as reproducible as possible, strong air cooling of the sonotrode is often used as an alternative or in addition to this solution in order to keep excessive heating or deformation as low as possible. It is also known to equip the sonotrode with cooling channels in the area of the sealing surface in order to keep the temperature of the sonotrode as constant as possible. However, homogeneous welding of very thin materials cannot be guaranteed in this way either.

The object of the present invention is therefore to provide a sonotrode for an ultrasonic welding device with which even very thin material layers can be welded to one another with high quality.

According to the invention, this object is achieved by a sonotrode of the type mentioned at the outset, the lower section having a slit, the slit extending from the sealing surface to a side of the lower section opposite the sealing surface, so that the lower section of the sonotrode is divided into several in a direction perpendicular to the longitudinal axis is divided into adjacent segments.

The subdivision of a lower section of the sonotrode means that the effect of thermal expansion is reduced and thus the sealing surface, which is divided into a plurality of sealing surface sections by the slits, is not curved. In other words, all sealing surface sections lie in one plane, come into contact with the material to be welded at the same time and exert the same pressure on the material to be welded. This means that even very thin layers of material can be welded together, where a convex curvature of the sealing surface would lead to an unsatisfactory welding result.

In one embodiment, the sonotrode is designed in such a way that u>0.25°, preferably 0.8°<u<1.5° and particularly preferably 0.95°<u<1.1°. Ideally, therefore, the length o of the upper section essentially corresponds to the length u of the lower section.

In this case, if the total length o + u of the sonotrode in the direction of the longitudinal axis corresponds to a wavelength λ, with which the sonotrode is excited during an ultrasonic welding process, this leads to the boundary between the upper section and the lower section in the area of an oscillation node of the excitation oscillation runs. Placing the boundary between the slotted lower section and the upper section in a node has the advantage that this is a low-stress and low-strain region. On the one hand, stresses between the individual segments are reduced, but the influence of the segments on the overall vibration behavior of the sonotrode is also minimized. Thus, the slits in the lower section have almost no influence on the vibration transmitted to the material.

The slots according to the invention in the lower section of the sonotrode thus minimize the thermal deformation of the sealing surface and at the same time the vibration behavior of the sonotrode is not significantly influenced, so that the welding result is optimized overall.

In a further embodiment, the sealing surface is delimited by two opposite side surfaces of the sonotrode running essentially parallel to one another, and the slot closes an angle of <90° and preferably an angle between 80° and 87° in the area of the sealing surface with the two side surfaces of the sonotrode a.

The arrangement of the slits at an angle to the side surfaces of the sonotrode, which are arranged perpendicularly to a direction of advance of the material during the welding process, means that a uniform welding result can be achieved over the entire width of the sonotrode. The width of the sonotrode is understood to be the extent of the sonotrode that comes into contact with the material to be processed during a welding process and thus corresponds to the width of the material that is processed simultaneously during a welding process. If the slits were arranged perpendicularly to the side surfaces, ie parallel to the feed direction, this would result in the sealing surface having areas in which no welding takes place. This would impair the tightness and the visual impression of the welded connection achieved. By arranging the slots at an angle to the side surfaces, however, welding takes place over the entire width of the sonotrode.

In this embodiment, the entire slot does not necessarily have to be arranged at an angle. It is sufficient if only a lower part of the slit, which connects to the sealing surface, is arranged at an angle. Such a configuration offers the advantage that it is easier to produce in terms of manufacturing technology.

In a further embodiment, the slot has two supporting walls, with a distance between the supporting walls tapering towards the sealing surface, the tapering preferably taking place in steps, with the distance at the sealing surface particularly preferably being less than or equal to 1 mm, preferably less than or equal to 0 .5 mm and particularly preferably less than or equal to 0.3 mm.

The tapering of the slits towards the sealing surface offers the advantage that, viewed in terms of surface area, only the smallest possible area of the sealing surface is interrupted by the slits. In this way, the effect of the slots on the welding result is kept as low as possible, apart from compensating for thermal expansion.

In a further embodiment, the slot has a widening at an end remote from the sealing surface, the sealing surface preferably being delimited by two opposite side surfaces of the sonotrode running essentially parallel to one another and the widening being in a plane of the two opposite side surfaces of the lower Section considered is circular.

Such widening offers the advantage of reducing stresses that may build up between the segments due to vibration of the sonotrode and thermal deformation.

In a further embodiment, a further widening is additionally arranged in the area of the stepped narrowing of the slot. Like the widening at the end of the slits facing away from the sealing surface, this further widening preferably has a circular cross-section in a plane of the two opposite side surfaces of the sonotrode. This arrangement also counteracts tension between the individual segments.

In a further embodiment, the sealing surface is delimited by two substantially parallel, opposite side surfaces and by a front and a rear surface of the sonotrode, with a width of the lower section between the front and the rear surface essentially a width of the upper section between corresponds to the front and rear surfaces.

In other words, in this embodiment, at least one dimension of the top and bottom sections is chosen to be essentially identical for the bottom and top sections. Since the lengths u and o of the upper and lower sections are preferably also essentially identical in the direction of the longitudinal axis, the extensions of the upper and lower section in two dimensions therefore essentially correspond to one another.

In one embodiment, the expansion in a third dimension between the substantially parallel, opposite side surfaces is less in the lower section than in the upper section. In other words, the sonotrode tapers in the lower section towards the sealing surface.

In a further embodiment, the extent of the sonotrode in the lower section is less than in the upper section, both between the front surface and the rear surface and between the opposite side surfaces running essentially parallel to one another. In this embodiment, the sonotrode tapers in two dimensions towards the sealing surface.

In a further embodiment, the number of slots and thus the width of the individual segments is selected such that the convex, thermal deformation of the sonotrode in the area of the sealing surface is less than 3 μm, preferably less than 2 μm. The deformation is measured in a direction parallel to the longitudinal axis between the edge of the sealing surface and the extension of the sonotrode in the middle of the sealing surface.

In a further embodiment, the lower section has a plurality of slots, each slot having two slot walls, a width of the segments between two adjacent slot walls of two adjacent slots being at most (u+o)/3, preferably (u+o)/4 and particularly preferably (u+o)/6.

It goes without saying that even in an embodiment with only one slit, the width of the segments between a slit wall and the front or rear surface of the sonotrode is also at most (u+o)/3, preferably (u+o)/4 and particularly preferred (u+o)/6.

The number of slots thus depends on the total width of the sonotrode between the front and rear surfaces of the sonotrode and the length u of the lower section and the length o of the upper section. Since the lengths u and o of the upper and lower sections are preferably chosen as a function of the wavelength with which the sonotrode is excited, the number of slots thus depends on the overall width of the sonotrode and the wavelength of the exciting ultrasonic vibration.

The total number of slots affects the vibration behavior of the sonotrode. The number of slots must therefore be chosen so that, on the one hand, sufficient compensation for the thermal deformation is achieved and, on the other hand, the vibration behavior of the sonotrode itself is influenced as little as possible.

In a further embodiment, the sealing surface is delimited by two opposite side surfaces running essentially parallel to one another and by a front and a rear surface of the sonotrode, the front surface being arranged at least on the sealing surface at an angle of <90° to the two opposite side surfaces is, preferably also the rear surface is arranged at least on the sealing surface at an angle of <90 ° to the two opposite side surfaces.

The arrangement of the front and preferably also the rear surface at an angle of <90° to the two opposite side surfaces offers the advantage that several of the sonotrodes according to the invention can be arranged next to each other in order to increase the processing width of an ultrasonic welding device without the weld seam being interrupted in the direction of the machining width. The angling of the front and rear faces is therefore based on the same consideration as the angling of the slots in the lower portion of the horn. In particular, it is also not necessary here for the entire front or rear surface to extend at a specific angle to the two opposite side surfaces. Rather, only the arrangement of the front and rear surfaces in the area of the sealing surface is important. Areas of the front and rear surfaces that do not directly adjoin the sealing surface can also be arranged at any other desired angle to the two opposite side surfaces.

In a further embodiment, the upper section of the sonotrode has at least one slot, the slot not being arranged in the extension of the slot of the lower section and/or the slot having a slot width which is greater than a distance between the slot walls of the slot.

The introduction of gaps in the upper section of the sonotrode has the advantage that the vibration behavior of the sonotrode and also the expansion of the sonotrode are kept stable during the excitation with the ultrasonic vibration in the direction of the processing width. If a sonotrode is excited with an ultrasonic vibration, the sonotrode also expands in a direction perpendicular to the feed direction of the material, ie in the processing width. This effect is already evident when the width of the sonotrode exceeds one third of the exciting wavelength of the ultrasonic vibration.

Since these slits, unlike the slits in the lower section, are not intended to compensate for thermal deformation, but only deformation due to ultrasonic vibration, the slits can be shaped differently, for example wider, and arranged independently of the slits. In particular, there is no connection between the slots of the lower section and the columns of the upper section.

In a further embodiment, a holder is provided for holding the sonotrode in an ultrasonic welding device, the holder being arranged on the segments of the lower section of the sonotrode.

The mounting of the sonotrode on the segments of the lower section offers the advantage that the vibration behavior of the sonotrode is essentially not influenced by the mounting. If the holder is arranged in an area in which the oscillation amplitude is lowest, this means that the position of the sonotrode has to be slightly readjusted in order to keep a processing distance between the sonotrode and the material to be processed constant.

With the arrangement of the holder on the segments in the lower section, the effect of thermal deformation is also lower, since there is less sonotrode material between the holder and the material to be processed, which can expand thermally. In addition, the thermal expansion is compensated by the slots in the lower section, so that the position of the sonotrode relative to the material to be processed can be readjusted in a significantly smaller range or, depending on the application, is not necessary at all.

1. a) Bereitstellen einer Sonotrode nach einem der Ansprüche 1-10,
2. b) Bereitstellen eines Gegenwerkzeuges mit einer Siegelfläche,
3. c) Anordnung des Materials zwischen der Siegelfläche der Sonotrode und der Siegelfläche des Gegenwerkzeugs,
4. d) Anregen der Sonotrode mit einer Ultraschallschwingung mit der Wellenlänge λ,
5. e) Übertragen der Ultraschallschwingung auf das Material.

The problem on which the invention is based is also solved by a method for ultrasonic processing of a material, the method having the following steps:

1. a) providing a sonotrode according to any one of claims 1-10,
2. b) providing a counter tool with a sealing surface,
3. c) arrangement of the material between the sealing surface of the sonotrode and the sealing surface of the counter tool,
4. d) exciting the sonotrode with an ultrasonic vibration with the wavelength λ,
5. e) transmitting the ultrasonic vibration to the material.

und vorzugsweise $$\mathrm{0,9}\left(\text{u+o}\right)<\mathrm{\lambda <1}\mathrm{,1}\left(\text{u+o}\right).$$

In a further embodiment of the method according to the invention, the wavelength λ is: $$0.8\left(\text{u+o}\right)<\mathrm{\lambda <1}\mathrm{,2}\left(\text{u+o}\right)$$

and preferably $$0.9\left(\text{u+o}\right)<\mathrm{\lambda <1}\mathrm{,1}\left(\text{u+o}\right).$$

The total length u+o of the sonotrode in the direction of the longitudinal axis preferably corresponds essentially to the wavelength λ with which the sonotrode is excited. In this case, it is also referred to as a λ sonotrode.

In one embodiment, in particular, 0.4λ<u<0.6λ and preferably λ/2=u applies. In other words, the extension of the slits in a direction of the longitudinal axis corresponds to half the wavelength. This also has advantages for the vibration behavior of the sonotrode, since the slits end in a vibration node of the ultrasonic vibration. In this case, the slots have almost no influence on the vibration behavior of the sonotrode and only compensate for the thermal deformation of the sonotrode.

In a further embodiment of the method according to the invention, during step e) the material is moved at a feed rate v>0 m/s between the sealing surface of the sonotrode and the sealing surface of the counter-tool.

By matching the feed speed to the process of ultrasonic welding, a welding method is thus provided which can process tubular and web-shaped materials in a cycled or continuous operation. The material to be processed is guided continuously through the welding tool and is processed at certain points or continuously with ultrasound, depending on the feed rate and the clocking or configuration of the welding tool. Corresponding methods are used, for example, in the packaging industry, with a tubular material into which product is filled being welded and severed at certain intervals in order to package the product individually. Further areas of application can also be found, for example, in the processing of web-shaped nonwovens, which are mainly processed in a continuous process in the hygiene industry.

• 1 zeigt eine dreidimensionale, schematische Darstellung einer Ausführungsform der erfindungsgemäßen Sonotrode.
• 2a zeigt eine Draufsicht auf die Siegelfläche der in 1 gezeigten Ausführungsform.
• 2b zeigt eine Vergrößerung des markierten Bereichs in 2a.
• 3a zeigt eine Seitenansicht auf eine Seitenfläche der in 1 gezeigten Ausführungsform.
• 3b zeigt eine Vergrößerung des in 3a markierten Bereichs.
• 4 zeigt eine weitere Seitenansicht auf die vordere Fläche der in 1 gezeigten Ausführungsform.
• 5 zeigt eine dreidimensionale, schematische Darstellung einer weiteren Ausführungsform der erfindungsgemäßen Sonotrode.
• 6 zeigt eine schematische Darstellung einer Ausführungsform der erfindungsgemäßen Sonotrode in einer Ultraschallschweißvorrichtung.

Further advantages, features and possible applications of the present invention become clear from the following description of various embodiments of the invention and the associated figures. Identical elements are denoted by the same reference symbols.

• 1 shows a three-dimensional, schematic representation of an embodiment of the sonotrode according to the invention.
• 2a shows a plan view of the sealing surface in 1 embodiment shown.
• 2 B shows an enlargement of the marked area in 2a .
• 3a shows a side view of a side face of in 1 embodiment shown.
• 3b shows an enlargement of the in 3a marked area.
• 4 shows another side view of the front surface of in 1 embodiment shown.
• 5 shows a three-dimensional, schematic representation of a further embodiment of the sonotrode according to the invention.
• 6 shows a schematic representation of an embodiment of the sonotrode according to the invention in an ultrasonic welding device.

In the 1 The embodiment shown of the sonotrode 1 according to the invention for an ultrasonic welding device can be divided into a lower section 10 of length u and an upper section 20 of length o. The upper section 20 and the lower section 10 are arranged next to one another on a longitudinal axis 100 of the sonotrode 1 . The total length of the sonotrode 1 in the direction of the longitudinal axis 100 is u + o. In addition, the length u of the lower section 10 corresponds to the length o of the upper section 20. In addition, a width 19 of the lower section 10 corresponds to a width 29 of the upper section 20.

Out of 4 it can be seen that the front surface 13 tapers towards the sealing surface 11 . An extension of the sonotrode 1 in the upper cut 20 and in an upper area of the lower section 10 in a plane of the front surface 13 is therefore larger than an extension of a lower area of the lower section 10 which adjoins the sealing surface 11 . The rear surface 14 is designed in exactly the same way as the front surface 13.

Furthermore, the lower section 10 has a sealing surface 11 which is aligned perpendicular to the longitudinal axis 100 and which in 2a is shown. The sealing surface 11 is intended to come into contact with a material 40 to be processed (see FIG 6 ). The width 19 corresponds to the width over which ultrasonic processing of the material 40 takes place with the sonotrode 1 according to the invention.

The lower section 10 of the sonotrode 1 has three slits 15 , the slit 15 extending from the sealing surface 11 to a side of the lower section 10 opposite the sealing surface 11 . The slot 15 has two slot walls spaced a distance 17 from each other (see Fig 2 B) .

Out of 3b it can also be seen that the slit 15 extends towards the sealing surface 11, with the taper being stepped. In the area of the stepped taper, a widening 18' is arranged, which has a circular cross-section in a plane of the side surface 12. The spacing of the slit walls in the area 15' of the slit 15, which is arranged between the widening 18' and the sealing surface 11, is also significantly smaller than a spacing 17 of the slit walls of the slit 15 above the widening 18'.

In addition to the widening 18 ′ in the region of the stepped narrowing, the slit 15 has a further widening 18 which is arranged at an end of the slit 15 which faces away from the sealing surface 11 . Viewed in a plane of the side surface 12, the widening 18 also has a circular cross section (see FIG 3a) .

The widenings 18, 18' prevent or at least reduce stresses that could form between the segments 10' during operation of the sonotrode 1 in an ultrasonic welding device due to the vibrations and thermal expansion of the sonotrode material.

In the 2a and 2 B it is also shown that the slots 15 in the area of the sealing surface 11 enclose an angle 16 of 81° with the side surface 12 of the sonotrode 1 . The side surfaces 12, 12' run parallel to one another, are arranged opposite one another and delimit the sealing surface 11 of the sonotrode 1. As in FIG 3a shown, the slits 15 are only arranged in a small area 15 ′ of a few millimeters from the sealing surface 11 in the direction of the longitudinal axis 100 at this angle 16 to the side surface 12 . In the adjoining area in the direction of the longitudinal axis 100, the slots 15 are arranged perpendicular to the two side surfaces 12, 12'.

In addition, from the 2a It can be seen that a front surface 13 and a rear surface 14 of the sonotrode 1, which delimit the sealing surface 11 in addition to the side surfaces 12, 12', are also arranged at an angle of <90° to the side surfaces 12. As a result, the sonotrode 1 according to the invention can be connected to other sonotrodes in order to increase the processing width of an ultrasonic welding device.

The slots 15 divide the lower section 10 of the sonotrode 1 into a plurality of segments 10 ′ lying next to one another in a direction perpendicular to the longitudinal axis 100 . The arrangement of the slots 15 in the lower section 10 of the sonotrode 1 reduces thermal deformation of the sealing surface 11, so that a more homogeneous welding result is achieved over the width 19 of the lower section 10.

In addition, two gaps 21 with a gap width 27 are arranged in the upper section 20 (see FIG 3a) . The gaps 21 serve to minimize an expansion of the sonotrode 1 in the width 29 of the upper section 20 during the operation of the sonotrode 1 in an ultrasonic welding device.

As in the 1 and 3 shown, the gaps 21 are independent of the slots 15, i.e. not arranged as an extension of them or on a common line, and also have a larger gap width 27, since the gaps 21 compensate for a different deformation effect of the sonotrode 1 than the slots 15

Ultimately, you know in the 1-4 shown embodiment on brackets 30 which are arranged in a region of the segments 10 'of the lower portion 10.

In the 5 shown embodiment of the sonotrode 1 according to the invention differs from that in FIGS 1-4 shown embodiment is that the brackets 30 are not arranged in the lower portion 10, but in the upper portion 20.

In 6 is the in 5 shown embodiment of the sonotrode 1 shown schematically in an ultrasonic welding device. A material 40 which is to be machined is arranged between the sonotrode 1 and a counter-tool 50 . The material 40 moves at a feed rate v>0 m/s in a feed direction 101 between the sonotrode 1 and the counter tool 50.

During the operation of the ultrasonic welding device, the sonotrode 1 is excited with an ultrasonic oscillation with the wavelength λ and this ultrasonic oscillation is transmitted to the material 40 via the sealing surface 11 . The material 40 is pressed against a sealing surface 51 of the counter tool 50 by the ultrasonic vibration, so that the material 40 is ultrasonically processed by the transmitted ultrasonic vibration. The material 40 can be, for example, several layers of non-woven fabric that are to be connected to one another in a materially bonded manner. When the sonotrode 1 hits the non-woven fabric 40, the latter begins to melt due to the frictional heat generated and connects to a material layer underneath.

The overall length o+u of the sonotrode 1 is chosen such that it essentially corresponds to the wavelength λ of the exciting ultrasonic vibration. In addition, the length of the slits 15, ie the length u of the lower section 10, corresponds to half the wavelength λ.

The choice of these dimensions ensures that the slots 15 optimally compensate for the thermal deformation of the sealing surface 11, but at the same time the vibration behavior of the sonotrode 1 is not significantly influenced. Thus, with the sonotrode 1 according to the invention, even very thin material layers 40 can be homogeneously welded to one another or generally processed with ultrasound.

Reference List

1

sonotrode

10

lower section

10'

segments

11

Sealing surface of the sonotrode

12, 12'

opposite side surfaces running parallel to one another

13

front face

14

back surface

15

slot

15'

partial section of the slit arranged towards the sealing surface

16

angle

17

Distance of the diaphragm walls

18, 18'

widening

19

Bottom section width

20

upper section

21

gap

27

gap width

29

Width of the top section

30

bracket

40

material

50

counter tool

51

Sealing surface of the counter tool

100

longitudinal axis

101

feed direction

Claims (14)

Sonotrode (1) for an ultrasonic welding device with a lower section (10) of length u and an upper section (20) of length o, the upper section (20) and the lower section (10) next to each other on a longitudinal axis (100) of the Sonotrode (1) are arranged and the total length of the sonotrode (1) in the direction of the longitudinal axis (100) is u + o, the lower section (10) having a sealing surface (11) aligned perpendicular to the longitudinal axis (100), the Sealing surface (11) is intended to come into contact with a material (40) to be processed, characterized in that the lower section (10) has a slit (15), the slit (15) extending from the sealing surface (11 ) to a side of the lower section (10) opposite the sealing surface (11), so that the lower section (10) of the sonotrode (1) is divided into several segments (10') lying next to one another in a direction perpendicular to the longitudinal axis (100). is divided. Sonotrode (1) according to the preceding claim, wherein u>0.25o, preferably 0.8o<u<1.5o and particularly preferably 0.95o<u<1.1o. Sonotrode (1) according to one of the preceding claims, wherein the sealing surface (11) is delimited by two opposite side surfaces (12, 12') of the sonotrode (1) running essentially parallel to one another and the slot (15) in the region of the sealing surface ( 11) with the two Side faces (12, 12') of the sonotrode (1) each enclose an angle (16) <90° and preferably an angle (16) between 80° and 87°. Sonotrode (1) according to one of the preceding claims, wherein the slot (15) has two slot walls, with a distance (17) between the slot walls tapering towards the sealing surface (11), the tapering preferably taking place in steps, with the Distance (17) is less than or equal to 1 mm, preferably less than or equal to 0.5 mm and particularly preferably less than or equal to 0.3 mm. Sonotrode (1) according to one of the preceding claims, wherein the slot (15) has a widening (18) at an end facing away from the sealing surface (11), the sealing surface (11) preferably being separated from two opposite side surfaces running essentially parallel to one another (12, 12') of the sonotrode (1) and wherein the widening (18) is circular when viewed in a plane of the two opposite side surfaces (12, 12'). Sonotrode (1) according to one of the preceding claims, wherein the sealing surface (11) is formed by two opposite side surfaces (12, 12') running essentially parallel to one another and by a front (13) and a rear (14) surface of the sonotrode (1 ) is limited, wherein a width (19) of the lower portion (10) between the front (13) and the rear (14) surface substantially a width (29) of the upper portion (20) between the front (13) and the rear (14) surface corresponds. Sonotrode (1) according to one of the preceding claims, wherein the lower section (10) has a plurality of slots (15), each slot (15) having two slot walls, a width of the segments between two adjacent slot walls of two adjacent slots (15) being at most (u+o)/3, preferably (u+o)/4 and more preferably (u+o)/6. Sonotrode (1) according to one of the preceding claims, wherein the sealing surface (11) is formed by two opposite side surfaces (12, 12') running essentially parallel to one another and by a front (13) and a rear (14) surface of the sonotrode (1 ) is limited, the front surface (13) being arranged at least on the sealing surface (11) at an angle of less than 90° to the two opposite side surfaces (12, 12'), the rear surface (14) preferably also being at least is arranged on the sealing surface (11) at an angle of less than 90° to the two opposite side surfaces (12, 12'). Sonotrode (1) according to one of the preceding claims, wherein the upper section (20) of the sonotrode (1) has at least one gap (21), the gap (21) not being in extension of the slot (15) of the lower section (10) is arranged and / or wherein the gap (21) has a gap width (27) which is greater than a distance (17) of the slot walls of the slot (15). Sonotrode (1) according to one of the preceding claims, wherein a holder (30) is provided for holding the sonotrode (1) in an ultrasonic welding device, the holder (30) on the segments (10') of the lower section (10) of the sonotrode (1) is arranged. Method for ultrasonic processing of a material (40) with the steps a) providing a sonotrode (1) according to one of Claims 1 until 10 , b) providing a counter tool (50) with a sealing surface (51), c) arranging the material between the sealing surface (11) of the sonotrode (1) and the sealing surface (51) of the counter tool (50), d) exciting the sonotrode ( 1) with an ultrasonic vibration of wavelength λ, e) transmitting the ultrasonic vibration to the material (40). procedure after claim 11 , where the wavelength λ is 0.8(u+o)<λ<1.2(u+o) and preferably 0.9(u+o)<λ<1.1(u+o). procedure after claim 12 , where 0.4λ < u < 0.6λ, preferably λ/2 = u. Procedure according to one of Claims 11 until 13 , wherein during step e) the material (40) is moved through at a feed rate v> 0 m/s in a feed direction (101) between the sealing surface (11) of the sonotrode (1) and the sealing surface (51) of the counter tool (50). .

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